# how to select training data for naive bayes classifier

I want to double check some concepts I am uncertain of regarding the training set for classifier learning. When we select records for our training data, do we select an equal number of records per class, summing to N or should it be randomly picking N number of records (regardless of class)?

Intuitively I was thinking of the former but thought of the prior class probabilities would then be equal and not be really helpful?

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It depends on the distribution of your classes and the determination can only be made with domain knowledge of problem at hand. You can ask the following questions:

• Are there any two classes that are very similar and does the learner have enough information to distinguish between them?
• Is there a large difference in the prior probabilities of each class?

If so, you should probably redistribute the classes.

In my experience, there is no harm in redistributing the classes, but it's not always necessary.

It really depends on the distribution of your classes. In the case of fraud or intrusion detection, the distribution of the prediction class can be less than 1%. In this case you must distribute the classes evenly in the training set if you want the classifier to learn differences between each class. Otherwise, it will produce a classifier that correctly classifies over 99% of the cases without ever correctly identifying a fraud case, which is the whole point of creating a classifier to begin with.

Once you have a set of evenly distributed classes you can use any technique, such as k-fold, to perform the actual training.

Another example where class distributions need to be adjusted, but not necessarily in an equal number of records for each, is the case of determining upper-case letters of the alphabet from their shapes.

If you take a distribution of letters commonly used in the English language to train the classifier, there will be almost no cases, if any, of the letter `Q`. On the other hand, the letter `O` is very common. If you don't redistribute the classes to allow for the same number of `Q`'s and `O`'s, the classifier doesn't have enough information to ever distinguish a `Q`. You need to feed it enough information (i.e. more `Q`s) so it can determine that `Q` and `O` are indeed different letters.

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i read about k-fold, as provided by @fyr. I'm confused. After I have the evenly distributed training sets per class, which sets do i provided to train the classifier for actual classifying use? My prior is i believe even: like c1: 90% and c2: 10%. –  goh Jul 6 '11 at 7:07
You create a whole new data set with evenly distributed classes. You then use this new data and partition it into training, cross-val, and test as needed. k-fold is a very common way to partition the data into training and cross-val. –  dacamo76 Jul 6 '11 at 15:37

The preferred approach is to use K-Fold Cross validation for picking up learning and testing data.

Quote from wikipedia:

K-fold cross-validation

In K-fold cross-validation, the original sample is randomly partitioned into K subsamples. Of the K subsamples, a single subsample is retained as the validation data for testing the model, and the remaining K − 1 subsamples are used as training data. The cross-validation process is then repeated K times (the folds), with each of the K subsamples used exactly once as the validation data. The K results from the folds then can be averaged (or otherwise combined) to produce a single estimation. The advantage of this method over repeated random sub-sampling is that all observations are used for both training and validation, and each observation is used for validation exactly once. 10-fold cross-validation is commonly used.

In stratified K-fold cross-validation, the folds are selected so that the mean response value is approximately equal in all the folds. In the case of a dichotomous classification, this means that each fold contains roughly the same proportions of the two types of class labels.

You should always take the common approach in order to have comparable results with other scientific data.

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